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Design of nastic cellular structures with osmotic actuation. Shape changing structures play an imperative role in aerospace, automobile, energy and other industries. This project aims to develop novel concepts extracted from nastic motion in plants and relevant computational algorithms for the design of nastic cellular structures with osmotic actuation. The project is of significance as it offers a potential solution to the shape morphing challenge in aircraft and automobile from biomimetics vie ....Design of nastic cellular structures with osmotic actuation. Shape changing structures play an imperative role in aerospace, automobile, energy and other industries. This project aims to develop novel concepts extracted from nastic motion in plants and relevant computational algorithms for the design of nastic cellular structures with osmotic actuation. The project is of significance as it offers a potential solution to the shape morphing challenge in aircraft and automobile from biomimetics viewpoint - nastic actuation. The expected outcomes will be: a new numerical method for designing nastic cellular structures; and, validated algorithms with a novel topological geometry representation and multi objectives and constraints for applications in morphing structures with multiple target shapes.Read moreRead less
A human-centric eXplainable Automated Vehicle. The aim is to create a computational model to address the inability of Automated Vehicles (AV), powered by Artificial intelligence, to self explain their behaviours. This project applies novel multidisciplinary methodologies in a real-world self-driving setting to formalise the essence of driving explanations. It explores the when, why and how a driver is seeking an explanation and what type of automated explanation is truly human-interpretable. Exp ....A human-centric eXplainable Automated Vehicle. The aim is to create a computational model to address the inability of Automated Vehicles (AV), powered by Artificial intelligence, to self explain their behaviours. This project applies novel multidisciplinary methodologies in a real-world self-driving setting to formalise the essence of driving explanations. It explores the when, why and how a driver is seeking an explanation and what type of automated explanation is truly human-interpretable. Expected outcomes include the discovery of an acceptable, transparent and ethical explanation system that helps humans to understand the AVs decision making. This field will continue to rise in prominence and produce much-needed work to improve the widespread adoption of AVs.Read moreRead less
Dual input clutchless power-shifting transmission for hybrid vehicles. This project studies a newly proposed clutchless power-shifting transmission (CPT) for hybrid and electric vehicle applications. It aims to design new methods and actuators for power-on gear change to realise the best possible performance of the CPT, and through simulation and experimentation evaluate the system performance and response under both steady state and transient conditions. The proposed transmission is expected to ....Dual input clutchless power-shifting transmission for hybrid vehicles. This project studies a newly proposed clutchless power-shifting transmission (CPT) for hybrid and electric vehicle applications. It aims to design new methods and actuators for power-on gear change to realise the best possible performance of the CPT, and through simulation and experimentation evaluate the system performance and response under both steady state and transient conditions. The proposed transmission is expected to significantly reduce the efficiency losses present in modern vehicles and establish new techniques for achieving gear and mode changes that do not rely on friction clutches. It is anticipated that these novel technologies will provide new direction for developing the next generation of very high efficiency automotive power train technologies.Read moreRead less
Modelling the cutting process and cutting performance in high-speed abrasive waterjet turning. This project will have a significant impact for the manufacturing industry by providing a new abrasive waterjet turning technology for producing highly reliable products from advanced, but difficult-to-machine, materials. It will also develop into a new branch of science by understanding the mechanics associated with the new turning process.
Impinging supersonic jets: stability and control - with application to cold spray. Understanding aero-acoustics instabilities of impinging supersonic jets is vital to improve the energy efficiency of cold spray manufacturing. This project will generate the necessary knowledge to understand and control these instabilities, in order to improve the cold spray process and to extend the range of application of impinging supersonic jets flows.
Electromagnetically Interconnected Suspension for Electrified Vehicles . This project aims to develop an innovative, electromagnetically interconnected suspension system to enhance vehicle ride comfort, stability and handling dynamics, and thus safety of electrified vehicles. Specifically, the project integrates a set of novel electromagnetic shock absorbers to form an effective electrical network so as to realise an electromagnetically interconnected suspension system. Advanced integrated con ....Electromagnetically Interconnected Suspension for Electrified Vehicles . This project aims to develop an innovative, electromagnetically interconnected suspension system to enhance vehicle ride comfort, stability and handling dynamics, and thus safety of electrified vehicles. Specifically, the project integrates a set of novel electromagnetic shock absorbers to form an effective electrical network so as to realise an electromagnetically interconnected suspension system. Advanced integrated control techniques can then be applied to improve vehicle performance and dynamics in three planes. The project will assist the rapid development of transportation electrification. The outcomes from this project will lead to tangible improvements in vehicle comfort and safety.Read moreRead less
Nanoparticles with structures that mimic enzymes for electrocatalysis. This project aims to create a new class of electrocatalysts with architectures inspired by enzymes. Electrocatalysts are the backbone of the modern energy economy. In the new electrocatalysts developed by the project, the intention is the active sites will be spatially separated from the bulk solution by nanopores, as enzymes do. This architecture allows the reaction environment to be altered from the bulk solution, active tr ....Nanoparticles with structures that mimic enzymes for electrocatalysis. This project aims to create a new class of electrocatalysts with architectures inspired by enzymes. Electrocatalysts are the backbone of the modern energy economy. In the new electrocatalysts developed by the project, the intention is the active sites will be spatially separated from the bulk solution by nanopores, as enzymes do. This architecture allows the reaction environment to be altered from the bulk solution, active transport of species to the active site and cascade reactions to be performed. This should give advantages in activity, selectivity and the ability to perform multistep reactions. The intended outcomes are better performing hydrogen fuel cells and more effective conversion of carbon dioxide into useful organic compounds.Read moreRead less
Innovative X-by-Wire Control Systems for Improved Vehicle Manoeuvrability and Stability. Future automobiles will be equipped with safety-critical ‘x-by-wire’ systems, such as ‘steer-by-wire’, ‘brake-by-wire’, and ‘drive-by-wire’, to enable active safety control and improve reliability and performance. This project aims to develop a new coordinated control strategy based on an in-depth understanding of the fundamental dynamics and stability characteristics of vehicles. Corresponding x-by-wire sys ....Innovative X-by-Wire Control Systems for Improved Vehicle Manoeuvrability and Stability. Future automobiles will be equipped with safety-critical ‘x-by-wire’ systems, such as ‘steer-by-wire’, ‘brake-by-wire’, and ‘drive-by-wire’, to enable active safety control and improve reliability and performance. This project aims to develop a new coordinated control strategy based on an in-depth understanding of the fundamental dynamics and stability characteristics of vehicles. Corresponding x-by-wire systems will then be implemented, using a novel networked bilateral-control concept and new haptic devices for enhancing the overall performance and safety of vehicles. This project will lead to the innovative design of vehicle active safety systems for automobile manufacturing in Australia and the rest of the world.Read moreRead less